Conductive substrate structure with conductive channels formed by using a two-sided cut approach and a method for manufacturing the same

ABSTRACT

A conductive substrate structure includes a substrate unit, a conductive pad unit, and a conductive layer unit. The substrate unit has a top surface, a bottom surface, two opposite lateral surfaces, and a front surface. The conductive pad unit has at least two first conductive pads separated from each other and disposed on the top surface, and at least two second conductive pads separated from each other and disposed on the bottom surface. The conductive layer unit has at least two first conductive layers formed on the front surface and respectively electrically connected to two front sides of the two first conductive pads, and at least two second conductive layers respectively formed on the two opposite lateral surfaces and respectively electrically connected to two opposite lateral sides of the two second conductive pads. The two first conductive layers are respectively electrically connected with the two second conductive layers.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a conductive substrate structure and a method for manufacturing the same, in particular, to a conductive substrate structure with conductive channels formed by using a two-sided cut approach and a method for manufacturing the same.

2. Description of Related Art

A substrate has top circuits on its top surface and bottom circuits on its bottom surface, wherein the top circuits are electrically connected to the bottom circuits by using conductive holes. The method of the prior art for manufacturing the conductive holes is that: forming a plurality of through holes on the substrate by laser or machine to drill through the substrate, and then filling conductive material into the through holes to complete the conductive holes in order to electrically connect the top circuits and the bottom circuits of the substrate.

SUMMARY OF THE INVENTION

In view of the aforementioned issues, the present invention provides a conductive substrate structure with conductive channels formed by using a two-sided cut approach and a method for manufacturing the same. The present invention has a plurality of openings passing through a substrate, and the openings are formed by cutting two surfaces of the substrate.

To achieve the above-mentioned objectives, the present invention provides a conductive substrate structure with conductive channels formed by using a two-sided cut approach, including: a substrate unit, a conductive pad unit, and a conductive layer unit. The substrate unit has a top surface, a bottom surface opposite to the top surface, two opposite lateral surfaces between the top surface and the bottom surface, and a front surface between the top surface and the bottom surface and on two front sides of the two lateral surfaces. The conductive pad unit has at least two first conductive pads separated from each other and disposed on the top surface of the substrate unit, and at least two second conductive pads separated from each other and disposed on the bottom surface of the substrate unit. The conductive layer unit has at least two first conductive layers formed on the front surface of the substrate unit and respectively electrically connected to two front sides of the two first conductive pads, and at least two second conductive layers respectively formed on the two opposite lateral surfaces of the substrate unit and respectively electrically connected to two opposite lateral sides of the two second conductive pads. The two first conductive layers are respectively electrically connected with the two second conductive layers.

To achieve the above-mentioned objectives, the present invention provides a method for manufacturing conductive substrate structures with conductive channels formed by using a two-sided cut approach. The method includes providing a substrate unit, and the substrate unit having a plurality of first conductive pads separated from each other and disposed on a top surface thereof, and a plurality of second conductive pads separated from each other and disposed on a bottom surface thereof; cutting the top surface of the substrate unit to form a plurality of first grooves on the top surface of the substrate unit; cutting the bottom surface of the substrate unit to form a plurality of second grooves on the bottom surface of the substrate unit, and each first groove and each second groove being joined with each other to form an opening; forming a conductive material in the first grooves, the second grooves, and the openings; removing one part of the conductive material in the first grooves; and than cutting the substrate unit along the first grooves and the second grooves so as to form the conductive substrate structures.

Therefore, the method of using laser or machine to drill through a substrate to form a plurality of through holes according to the prior art is replaced by the method of cutting the substrate unit to form the openings according to the present invention.

In order to further understand the techniques, means, and effects the present invention takes for achieving the prescribed objectives, the following detailed descriptions and appended drawings are hereby referred; such that, through which the purposes, features, and aspects of the present invention can be thoroughly and concretely appreciated; however, the appended drawings are merely provided for reference and illustration, without any intention to be used for limiting the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a flowchart of the method for manufacturing conductive substrate structures with conductive channels formed by using a two-sided cut approach according to the present invention;

FIGS. 2 to 8B are schematic views of the conductive substrate structure with conductive channels formed by using a U-cutting tool according to the present invention, at different stages of the manufacturing processes, respectively; and

FIGS. 9A to 9D are schematic views of the conductive substrate structure with conductive channels formed by using a V-cutting tool according to the present invention, at different stages of the manufacturing processes, respectively.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring to FIG. 1, the present invention provides a method for manufacturing conductive substrate structures with conductive channels formed by using a two-sided cut approach. The method includes providing a substrate unit (the substrate unit has a plurality of first conductive pads separated from each other and disposed on a top surface thereof and a plurality of second conductive pads separated from each other and disposed on a bottom surface thereof); cutting the top surface of the substrate unit to form a plurality of first grooves on the top surface of the substrate unit; cutting the bottom surface of the substrate unit to form a plurality of second grooves on the bottom surface of the substrate unit, and each first groove and each second groove are joined with each other to form an opening; forming a conductive material in the first grooves, the second grooves, and the openings; removing one part of the conductive material in the first grooves; and then cutting the substrate unit along the first grooves and the second grooves to form the conductive substrate structures.

Referring to FIGS. 2 to 8B, the present invention has the follow detail manufacturing processes:

The step S100 is that: referring to FIGS. 1 and 2, providing a substrate unit 1′ that has a plurality of first conductive pads 20A separated from each other and disposed on a top surface 11′ thereof and a plurality of second conductive pads 20B separated from each other and disposed on a bottom surface 12′ (as shown in FIG. 2) thereof. The positions and the number of the first conductive pads 20A respectively correspond to the positions and the number of the second conductive pads 20B. In addition, the substrate unit can be a wafer, a printed circuit board, or a substrate made of any insulative material.

The step S102 is that: referring to FIGS. 1, 3A, and 3B, cutting the top surface 11′ of the substrate unit 1′ by using a U-cutting tool to form a plurality of first grooves A with U shape on the top surface 11′ of the substrate unit 1′. In addition, the depth of each first groove A is larger than ½ thickness of the substrate unit 1′, and the first grooves A are respectively formed on two lateral sides of each row of the first conductive pads 20A.

The step S104 is that: referring to FIGS. 1, 4A, and 4B (FIG. 4B is a bottom diagram of FIG. 4A), cutting the bottom surface 12′ of the substrate unit 1′ by using a U-cutting tool to form a plurality of second grooves B with U shape on the bottom surface 12′ of the substrate unit 1′, and each first groove A and each second groove B are joined with each other to form an opening C (as shown in FIG. 4B). In addition, the depth of each second groove B is larger than ½ thickness of the substrate unit 1′, and the second grooves B are respectively formed on two lateral sides of every two rows of the second conductive pads 20B.

The step S106 is that: referring to FIGS. 1, 5A, and 5B (FIG. 5A shows an enlarged view of X part of FIG. 4A, and FIG. 5B is a bottom diagram of FIG. 5A), forming a conductive material D in the first grooves A, the second grooves B, and the openings C by electroplating, evaporating, sputtering, or any forming method.

The step S108 is that: referring to FIGS. 1 and 6, removing one part of the conductive material D in the first grooves A. In other words, in the step of S106, the first conductive pads 20A on the top surface 11′ of the substrate unit 1′ are divided into a plurality of first conductive pad sets 20A′, and each first conductive pad set 20A′ has at least two first conductive pads 20A. In addition, the part of the conductive material D that is between two first conductive pads 20A of each first conductive pad set 20A′ is removed by matching exposure, development, and etching in order to insulate the two first conductive pads 20A of each first conductive pad set 20A′ from each other.

The step S110 is that: referring to FIGS. 1, 7A, 7B, 8A and 8B, cutting the substrate unit 1′ along the first grooves A and the second grooves B to form the conductive substrate structures (as shown in FIGS. 8A and 8B). In addition, the substrate unit 1′ is cut along the first grooves A and the second grooves B by using a cutting tool (not shown), and the width of the cutting tool is smaller than the widths of the first grooves A and the second grooves B.

Referring to FIGS. 8A and 8B, the present invention provides a conductive substrate structure with conductive channels formed by using a two-sided cut approach, including: a substrate unit 1, a conductive pad unit 2, and a conductive layer unit 3.

The substrate unit 1 has a top surface 11, a bottom surface 12 opposite to the top surface 11, two opposite lateral surfaces 13, 14 between the top surface 11 and the bottom surface 12, and a front surface 15 between the top surface 11 and the bottom surface 12 and on two front sides of the two lateral surfaces 13, 14. In addition, the substrate unit 1 can be an insulative body.

The conductive pad unit 2 has at least two first conductive pads 20A separated from each other and disposed on the top surface 11 of the substrate unit 1, and at least two second conductive pads 20B separated from each other and disposed on the bottom surface 12 of the substrate unit 1. In addition, the two first conductive pads 20A are insulated from each other, and the two second conductive pads 20B are insulated from each other.

Moreover, the conductive layer unit 3 has at least two first conductive layers 30A formed on the front surface 15 of the substrate unit 1 and respectively electrically connected to two front sides of the two first conductive pads 20A, and at least two second conductive layers 30B respectively formed on the two opposite lateral surfaces 13, 14 of the substrate unit 1 and respectively electrically connected to two opposite lateral sides of the two second conductive pads 20B. The two first conductive layers 30A are respectively electrically connected with the two second conductive layers 30B. In addition, one of the two first conductive pads 20A is connected to one of the two second conductive pads 20B by electrically connecting one of the two first conductive layers 30A with one of the two second conductive layers 30B (as the direction of the arrow shown in FIG. 8A), and the other one of the two first conductive pads 20A is connected to the other one of the two second conductive pads 20B by electrically connecting the other one of the two first conductive layers 30A with the other one of the two second conductive layers 30B.

Furthermore, the front surface 15 of the substrate unit 1 is divided into an upper portion 15A and a lower portion 15B. The area of the upper portion 15A of the front surface 15 is larger than that of the lower portion 15B of the front surface 15, and the height of the upper portion 15A of the front surface 15 is smaller than that of the lower portion 15B of the front surface 15. In addition, the lower portion 15B of the front surface 15 is a lower plane 150, the upper portion 15A of the front surface 15 has an upper plane 151 and a cambered face 152 connected between the upper plane 151 and the lower plane 150, and the cambered face 152 has two cambered lines 1520 respectively on two opposite sides thereof. The two first conductive pads 20A are formed on the upper plane 151 and the cambered face 152 of the upper portion 15A of the front surface 15.

Moreover, the lateral surface 13 may be an example as shown in FIG. 8A, each lateral surface 13 of the substrate unit 1 is divided into an upper portion 13A and a lower portion 13B. The area of upper portion 13A of each lateral surface 13 is smaller than that of the lower portion 13B of each lateral surface 13, and the height of upper portion 13A of each lateral surface 13 is larger than that of the lower portion 13B of each lateral surface 13. In addition, the upper portion 13A of each lateral surface 13 is an upper plane 130, the lower portion 13B of each lateral surface 13 has a lower plane 131 and a cambered face 132 connected between the lower plane 131 and the upper plane 130, and the cambered face 132 has two cambered lines 1320 respectively on two opposite sides thereof. Each second conductive layer 30B is formed on the lower plane 131 and the cambered face 132 of the lower portion 13B of each lateral surface 13.

Furthermore, the lateral surface 14 may be an example as shown in FIG. 8 a, each lateral surface 14 of the substrate unit 1 is divided into an upper portion and a lower portion. The area of upper portion of each lateral surface 14 is smaller than that of the lower portion of each lateral surface 14, and the height of upper portion of each lateral surface 14 is larger than that of the lower portion of each lateral surface 14. In addition, the upper portion of each lateral surface 14 is an upper plane, the lower portion of each lateral surface 14 has a lower plane and a cambered face connected between the lower plane and the upper plane, and the cambered face has two cambered lines respectively on two opposite sides thereof. Each second conductive layer 30B is formed on the lower plane and the cambered face of the lower portion of each lateral surface 14.

In addition, the substrate unit 1 has a rear surface 16 between the top surface 11 and the bottom surface 12 and on two rear sides of the two lateral surfaces 13, 14. The rear surface 16 is opposite to the front surface 15. The conductive layer unit 3 has at least two another first conductive layers 30A′ formed on the rear surface 16 of the substrate unit 1 and respectively electrically connected to two rear sides of the two first conductive pads 20A, and the above-mentioned another two first conductive layers 30A′ are respectively electrically connected with the two second conductive layers 30B.

Furthermore, referring to FIG. 8B, the rear surface 16 of the substrate unit 1 is divided into an upper portion 16A and a lower portion 16B. The area of the upper portion 16A of the rear surface 16 is larger than that of the lower portion 16B of the rear surface 16, and the height of the upper portion 16A of the rear surface 16 is smaller than that of the lower portion 16B of the rear surface 16. In addition, the lower portion 16B of the rear surface 16 is a lower plane 160, the upper portion 16A of the rear surface 16 an upper plane 161 and a cambered face 162 connected between the upper plane 161 and the lower plane 160, and the cambered face 162 has two cambered lines 1620 respectively on two opposite sides thereof. The above-mentioned another two first conductive pads 30A′ are formed on the upper plane 161 and the cambered face 162 of the upper portion 16A of the rear surface 16.

Referring to FIGS. 9A to 9D, the present invention provides another method for manufacturing the conductive substrate structures by using V-cutting tool.

Referring to FIG. 9A, cutting the top surface 11 a′ of the substrate unit 1 a′ by using a V-cutting tool to form a plurality of first grooves Aa with V shape on the top surface 11 a′ of the substrate unit 1 a′. In addition, the depth of each first groove Aa is larger than ½ thickness of the substrate unit 1 a′, and the first grooves Aa are respectively formed on two lateral sides of each row of the first conductive pads 20A.

Referring to FIG. 9B, cutting the bottom surface 12 a′ of the substrate unit 1 a′ by using a V-cutting tool to form a plurality of second grooves Ba with V shape on the bottom surface 12 a′ of the substrate unit 1 a′, and each first groove Aa and each second groove Ba are joined with each other to form an opening (not shown). In addition, the depth of each second groove Ba is larger than ½ thickness of the substrate unit 1 a′, and the second grooves Ba are respectively formed on two lateral sides of every two rows of the second conductive pads (not shown).

Referring to FIG. 9C, the front surface 15 a of the substrate unit 1 a is divided into an upper portion 15A and a lower portion 15B. The area of the upper portion 15A of the front surface 15 a is larger than that of the lower portion 15B of the front surface 15 a, and the height of the upper portion 15A of the front surface 15 a is smaller than that of the lower portion 15B of the front surface 15 a. In addition, the lower portion 15B of the front surface 15 a has a lower inclined face 150 a, and the upper portion 15A of the front surface 15 a has an upper inclined face 151 a.

Moreover, the lateral surface 13 a may be an example as shown in FIG. 9C, each lateral surface 13 a of the substrate unit 1 a is divided into an upper portion 13A and a lower portion 13B. The area of upper portion 13A of each lateral surface 13 a is smaller than that of the lower portion 13B of each lateral surface 13 a, and the height of upper portion 13A of each lateral surface 13 a is larger than that of the lower portion 13B of each lateral surface 13 a. In addition, the upper portion 13A of each lateral surface 13 a has an upper inclined face 130 a, and the lower portion 13B of each lateral surface 13 a has a lower inclined face 131 a. Each second conductive layer 30B is formed on the lower inclined face 131 a of the lower portion 13B of each lateral surface 13 a.

In addition, referring to FIG. 9D, the rear surface 16 a of the substrate unit 1 a is divided into an upper portion 16A and a lower portion 16B. The area of the upper portion 16A of the rear surface 16 a is larger than that of the lower portion 16B of the rear surface 16 a, and the height of the upper portion 16A of the rear surface 16 a is smaller than that of the lower portion 16B of the rear surface 16 a. In addition, the lower portion 16B of the rear surface 16 a has a lower inclined face 160 a, and the upper portion 16A of the rear surface 16 a has an upper inclined face 161 a.

Therefore, the method of using laser or machine to drill a substrate to form a plurality of through holes according to the prior art is replaced by the method of cutting the substrate unit by using a U-cutting tool or a V-cutting tool to form the openings according to the present invention.

The above-mentioned descriptions represent merely the preferred embodiment of the present invention, without any intention to limit the scope of the present invention thereto. Various equivalent changes, alternations, or modifications based on the claims of present invention are all consequently viewed as being embraced by the scope of the present invention. 

1. A conductive substrate structure, comprising: a substrate unit having a top surface, a bottom surface opposite to the top surface, two opposite lateral surfaces between the top surface and the bottom surface, and a front surface between the top surface and the bottom surface and on two front sides of the two lateral surfaces, wherein the front surface of the substrate unit is divided into an upper portion and a lower portion, the area of the upper portion of the front surface is larger than that of the lower portion of the front surface, and the height of the upper portion of the front surface is smaller than that of the lower portion of the front surface; a conductive pad unit having at least two first conductive pads separated from each other and disposed on the top surface of the substrate unit and at least two second conductive pads separated from each other and disposed on the bottom surface of the substrate unit; and a conductive layer unit having at least two first conductive layers formed on the front surface of the substrate unit and respectively electrically connected to two front sides of the two first conductive pads, and at least two second conductive layers respectively formed on the two opposite lateral surfaces of the substrate unit and respectively electrically connected to two opposite lateral sides of the two second conductive pads, wherein the two first conductive layers are respectively electrically connected with the two second conductive layers.
 2. The conductive substrate structure according to claim 1, wherein the substrate unit is an insulative body, the two first conductive pads are insulated from each other, the two second conductive pads are insulated from each other, one of the two first conductive pads is connected to one of the two second conductive pads by electrically connecting one of the two first conductive layers with one of the two second conductive layers, and the other one of the two first conductive pads is connected to the other one of the two second conductive pads by electrically connecting the other one of the two first conductive layers with the other one of the two second conductive layers.
 3. The conductive substrate structure according to claim 1, wherein the two first conductive pads are formed on the upper portion of the front surface.
 4. The conductive substrate structure according to claim 1, wherein the lower portion of the front surface is a lower plane, the upper portion of the front surface has an upper plane and a cambered face connected between the upper plane and the lower plane, and the cambered face has two cambered lines respectively on two opposite sides thereof.
 5. The conductive substrate structure according to claim 4, wherein the two first conductive pads are formed on the upper plane and the cambered face of the upper portion of the front surface.
 6. The conductive substrate structure according to claim 1, wherein each lateral surface of the substrate unit is divided into an upper portion and a lower portion, the area of upper portion of each lateral surface is smaller than that of the lower portion of each lateral surface, and the height of upper portion of each lateral surface is larger than that of the lower portion of each lateral surface.
 7. The conductive substrate structure according to claim 6, wherein each second conductive layer is formed on the upper portion of each lateral surface.
 8. The conductive substrate structure according to claim 7, wherein the upper portion of each lateral surface is an upper plane, the lower portion of each lateral surface has a lower plane and a cambered face connected between the lower plane and the upper plane, and the cambered face has two cambered lines respectively on two opposite sides thereof.
 9. The conductive substrate structure according to claim 8, wherein each second conductive layer is formed on the lower plane and the cambered face of the lower portion of each lateral surface.
 10. The conductive substrate structure according to claim 1, wherein the substrate unit has a rear surface between the top surface and the bottom surface and on two rear sides of the two lateral surfaces, the rear surface is opposite to the front surface, the conductive layer unit has at least two another first conductive layers formed on the rear surface of the substrate unit and respectively electrically connected to two rear sides of the two first conductive pads, and the above-mentioned another two first conductive layers are respectively electrically connected with the two second conductive layers.
 11. The conductive substrate structure according to claim 10, wherein the rear surface of the substrate unit is divided into an upper portion and a lower portion, the area of the upper portion of the rear surface is larger than that of the lower portion of the rear surface, and the height of the upper portion of the rear surface is smaller than that of the lower portion of the rear surface.
 12. The conductive substrate structure according to claim 11, wherein the above-mentioned another two first conductive pads are formed on the upper portion of the rear surface.
 13. The conductive substrate structure according to claim 11, wherein the lower portion of the rear surface is a lower plane, the upper portion of the rear surface has an upper plane and a cambered face connected between the upper plane and the lower plane, and the cambered face has two cambered lines respectively on two opposite sides thereof.
 14. The conductive substrate structure according to claim 13, wherein the above-mentioned another two first conductive pads are formed on the upper plane and the cambered face of the upper portion of the rear surface.
 15. A conductive substrate structure, comprising: a substrate unit having a top surface, a bottom surface opposite to the top surface, two opposite lateral surfaces between the top surface and the bottom surface, and a front surface between the top surface and the bottom surface and on two front sides of the two lateral surfaces, wherein each lateral surface of the substrate unit is divided into an upper portion and a lower portion, the area of upper portion of each lateral surface is smaller than that of the lower portion of each lateral surface, and the height of upper portion of each lateral surface is larger than that of the lower portion of each lateral surface; a conductive pad unit having at least two first conductive pads separated from each other and disposed on the top surface of the substrate unit and at least two second conductive pads separated from each other and disposed on the bottom surface of the substrate unit; and a conductive layer unit having at least two first conductive layers formed on the front surface of the substrate unit and respectively electrically connected to two front sides of the two first conductive pads, and at least two second conductive layers respectively formed on the two opposite lateral surfaces of the substrate unit and respectively electrically connected to two opposite lateral sides of the two second conductive pads, wherein the two first conductive layers are respectively electrically connected with the two second conductive layers.
 16. A conductive substrate structure, comprising: a substrate unit having a top surface, a bottom surface opposite to the top surface, two opposite lateral surfaces between the top surface and the bottom surface, a front surface between the top surface and the bottom surface and on two front sides of the two lateral surfaces, and a rear surface opposite to the front surface and formed between the top surface and the bottom surface and on two rear sides of the two lateral surfaces, wherein the rear surface of the substrate unit is divided into an upper portion and a lower portion, the area of the upper portion of the rear surface is larger than that of the lower portion of the rear surface, and the height of the upper portion of the rear surface is smaller than that of the lower portion of the rear surface; a conductive pad unit having at least two first conductive pads separated from each other and disposed on the top surface of the substrate unit and at least two second conductive pads separated from each other and disposed on the bottom surface of the substrate unit; and a conductive layer unit having at least two first conductive layers formed on the front surface of the substrate unit and respectively electrically connected to two front sides of the two first conductive pads, and at least two second conductive layers respectively formed on the two opposite lateral surfaces of the substrate unit and respectively electrically connected to two opposite lateral sides of the two second conductive pads, wherein the two first conductive layers are respectively electrically connected with the two second conductive layers. 